potts



Aug. 27, 1940. LA M. PoT'rs Re- 2115.543

LINECASTING AND COMPOSING MACHINE l Original Filed Jan. 2, 1932 13 Sheets-Sheet l INVENTOR LOUIS M. DOTTS ATTORNEY kAug. 27, `1940.

L. M, POTTS LINECASTING AND COMPOSING MACHINE original Filed Jan. 2, 1952 uit* 247 13 sheets-Sheet 2 INVENTOR LOUIS M. POTTS BY I ATTORNE Aug.27,1940.

l.. M. POT-rs Re 215543 LINECASTING AND COMPOSING MACHINE ATTORNEY Aug. 27, 1940. L. M. POTTS Re. 21,543v

` LINECASTING AND COMPOSING' MACHINE original Filed Jan. 2, 1932 15 sheets-sheet 5 lMIIIIIIH I CONT/20L U/v/T INVENTOR LOUlS M. POTTS ATTORNE L. M. POTTS Aug. 27, l 94.

LINECASTING AND COMPOSING MACHINE Original Filed Jan. 2, 1932 13 Sheets-Sheet 6 INVENTOR LOUIS M. DOTTS BYM ATTORNEY Aug. 27, 1940. l.. M. PoTTs LINECASTING AND COMPOSING MACHINE Original Filed Jan. 2, 1932 13 Sheets-Sheet T ATTORNE R 0 T N E V N LOUIS M. DOTTS NNN Aug 27, 1940- 1 M. PoTTs Re. 21,543

LINECASTING AND COMPOSING MACHINE '13 Sheets-Sheet 9 Original Filed Jan. 2, 1932 INVENTOR 64 oUls M. DoTTs ATTORNEY l L. M. POTTS Aug. 27, 1940.

LINECASTING AND COMPOSING MACHINE 15 Sheets-Sheet lO Original Filed Jan. 2, 1932 lll'llllll MMOMLLMJE@ 9.97

INVENTOR LOUIS M. POTTS BW@ ATTORN Y Allg 27, 1940- l.. M. Po'r-rs LINECASTING' AND yCOMPOSINCY MAHINE 13 sheets-sheet 11 Original Filed Jan. 2, 1932 S T m RD. H o m MM o E U VQ'Q mU m Y B Aug. 27, 1940. L M pQ-r-rs Re. 21,543

` LINECASTING AND COMPOSING MACHINE Original Filed Jan. 2, 1932 13 Sheets-Sheet l2 INVENTOR LOUIS M. DOTTS BY I ATTORNE Aug. 27, 1940. V M, POT-rs Re. 21,543

LINECASTING AND COMPOSING MACHINE l Original Filed Jan. 2, 1932 13 Sheets-Sheet 13 267 I @a F-IG. E] LomENrDo-r'rs ATTORNEY Ressued Aug. 27, 1940 UNITED STATES PATENT OFFICE LINECASTING ANDy o'oMPo SING MACHINE Louis M. Potts, Evanston, Ill., assgnor, by mesne assignments, to Teletypesetter Corporation, a corporation of Delaware original N0. 2,057,652, dates october 13, 1936, se-

rial No. 584,387, January 2, 1932. Application for reissue October 4, 1938, Serial No. 233,337

76 Claims.

and in the hereunto appended claims and include A'he unit comprises generallyv a signal controlled mechanism that is responsive to either various permutations of transverse perforations of a control tape or to corresponding electrical impulses and a selector mechanism'that is responsive to the signal controlled mechanism and operates to select one of a plurality of matrix or function bars. Actuating mechanism deriving its power from the principal machine functions to move the selected one of the plurality of bars whereby the latter is made to complete the particular performance for which it was selected. Certain of the plurality of bars are adapted to release matrices from the storage magazine of the principal machine and certain others of them are adapted toexecute special functions such as to initiate the movement .of the assembling elevator of the principal machine or to control functions in the control unit itself.

Line casting machines are characteristically complex mechanismsv and may therefore be subjected to relatively high factors of error during given periods of operation. The structure of the present invention has been provided with several safety devices whereby, in the event of any-irregular operation or disorder, `such as, for example, jamming of matrices in transit or premature elevator operation, the transmission of operating signals by a record reader is automatically suspended and remains so until a local supervisor manually restores the machine to proper operating condition.

The unit is preferably equipped with control mechanism already referred to, whereby the machine may be operated from a remote electrical' signaling. source, as by the use of selector mechanism as disclosed fully in Patent No. 1,970,567,

issued Augustl 2l, 1934. A removable keyboard which may be conveniently installed above the selector bars is also provided so that in the event it is desired tomanually operate a line casting machine equipped with the present invention this may be done without interfering with the automatic control mechanism.

It will be observed that the installation of the present invention upon a` standard line casting machine, such as the commercially well known machines, involves but slight adaptations or changes from the standard equipment provided with either of these devices. The space occupied by this mechanism is but slightly greater than that occupied by the standard manual keyboard. Thus, the conversion of a manually controlled device toI one which is automatically controlled requires butv slight sacrifice of space.

Certain variations exist in the manner in which some special functions are manually performed in several different models of standard line casting machines. The present invention, While generally adaptable to the several of these models, varies specifically in some of its details of attachment. However, the selection mechanism of the present device as well as the timing arrangement of certain of its essential parts are so versatile in design that the same equipment may be adapted to control any of several standard models.

A better understanding of the present invention may be obtained from the following description taken in conjunction with the accompanying drawings wherein,

Fig.- l is a perspective view of a principal machine with parts eliminated showing the application of the present invention thereto.

Fig. 2 is a plan View of the keyboard control mechanism with certain parts broken away. n

Fig. 3 is a sectional view taken approximately on line 3 3 of Fig. 2.

Fig.- 4 is a right side elevational View of the keyboard mechanism with parts broken away.

Fig. Lla is a detail sectional view illustrating a push bar in actuated position.

Fig. 5 is a( sectional View taken approximately on line 5 5 of Fig. 2.

Fig. 5a is a diagram of a simple control circuit used in coordinating the several parts of the present invention.

Fig. 5b is a circuit diagram illustrating a mately on line 9-9 of Fig. 2.

Fig. 9a is a fragmentaryperspective view illustrating the seventh bar shift mechanism.

Fig. 10 is a detail sectional view of the automatic channel shift mechanism and is taken approximately on line IIJ-I0 of Fig. 2.

Flg. 11 is a detail plan view of the channel shift mechanism.

Fig. 12 is a transverse sectional detail view illustrating one form of application of a magagg zine shift mechanism.

Fig. 13 is a transverse sectional detail view similar to Fig. 12, but somewhat enlarged illustrating a modified application of a magazine shift mechanism.

g5 Fig. 14 is a detail sectional view taken approximately on line |4-l4 of Fig. 2 illustrating a short-long lineV interceptor device.

Fig. 14a is a fragmentary detail elevation of a mechanism for quadding out a line in response to a single signal. v

Fig. 14h is a sectional view taken on line IIb-|41) of Fig. 14a.

Fig. 15 is a detailV plan view of the short-long line interceptor illustrated in Fig. 14.

Fig. 16 is a perspective/view with parts broken away showing the assembling elevator control mechanism.

Fig. 17 isa perspective view of a circuit breaker mechanism.

Figs. 18 and 19 are detail sectional views of the removable keyboard.

Fig. 20 is a detail sectional View illustrating a feature of the present invention for determining the rail of the assembling frame upon which subsequently selected matrices shall assemble.

Fig. 21 is a sectional view taken approximately on line 2|2| of Fig. 20.

Fig. 21a is a detail sectional view taken on line 2|a-2Ia of Fig. 20.

Fig. 22 is a detail view of a modified form of the invention illustrated in Fig. 20.

Fig. 22a is a perspective view of an assembler block with parts broken,` away to show the operation of the movable shift rail.

Fig. 23 is a detail sectional view illustrating a modified form of record reader.

Referring to the drawings in which like reference characters designate similar parts throughout the drawings, Fig. 1 illustrates generally frame work 3| of the appliance comprising the present invention, as well as several of the prominent operating mechanisms. 'I'he preferred mode of control for this invention is by a perforated record strip 32 which may be prepared by suitable perforating mechanism in the manner fully described in Patent No. 2,000,029, issued May 7, 1935. After preparation, the tape 32 is fed through a record reader 33 in a step-by-step manner whereby each transverse row of perforatlons is mechanically translated to a corresponding positionment of code bars 34 (Fig. 2). In accordance with each such positionment of the code bars 34, rthe selector bar 35 individual to the particular code perforations in the tape is released into operative relation with a push bar 36 .ing the time that the principal machine is in opwhich is in turn actuated to effect the release of a selected matrix or to perform a special function depending on the character of the selection.

The record reader 33 carries a set of feelers 45 each of which registers opposite one of the per- 5 forations of a transverse row. The feelers 45 and their associated tail rods 46 are spring urged to assume the dotted line position as indicated in Fig. 3 when permitted to do` so by the occurrence of a hole in the particular position of the tape 32. When, however, noI hole is presented the elements 45 for those particular positions across the tape remain in the solid line position as shown.

The unit derives all of its operating power from the principal machine through the medium of a 15 driving pulley 31 attached to the intermediate shaft 38 which drives pulley wheel `33 by means of a belt 4 I. Pulley wheel 39 is secured to a main l drive shaft 42 which'is constantlyv rotated dur- 20 eration and which transmits a similar, but somewhat slower motion to an auxiliary drive shaft 4-3 by means of the gear train 44. The ratio between the driving pulley 31 and the driven pulley 39, or in other words, the speed at which the control unit may be operated, is dependent upon the speed at which the principal machine is capable of being operated.

'I'he record reader mechanism is operated by a cam shaft 41 which is an extension of the auxiliary drive shaft 43. Main drive shaft 42 has an extension shaft 48, while a stub drive shaft 49 gear driven as at 5| from the main drive shaft 4-2 is provided with a cam sleeve 52 (Fig. 5) Thus is indicated in a general way the distribution of 85 the driving and operating power.

Referring especially to Figs. 2, 3 and 5 attention is directed to the frame structure 3| having a rectangular portion 53 which may be secured to the keyboard supporting base of the standard line casting machine. 'Iwo transverse ribs 54 and 55 serve to support some of the mechanism as well as to reinforce the rectangular portion 53. At the rearward side of the frame 3| and securely fastened thereto is an angular bracket 56 having a depending portion 51.

Another rectangular frame 58 superimposed upon the rectangular portion 53 of the frame 3| is provided at its rearmost side with an upright bracket 59. As is bestlndicated in Fig. 5 this frame 58 serves asa supporting fixture for the selec-tor bars while the bracket 59 correspondingly maintains the push bars or weights 36 in a position at one end and above the inner extremlties of the selector b-ars. For each movement of the code bars 34 in varying combinations, as they are controlled by the record reader 33, one of the selector bars 35 is urged into its dotted position, as indicated, by the action of an associated spring 6| (Fig. 5). 60

Selector mechanism This movement of a bar 35 displaces the push bar 36 corresponding to it so as to cause it to assume the dotted line position indicated. When, 65 after this has happened'a bail 62 makes its next oscillation the control of which will be more fully described hereinafter, its upturned lip 63 engages the depending leg 64 of the bar 36 thus displaced, and pushes it upwardly until its abut- 70 ment lobe 65 engages and actuates a corresponding matrix release reed 66. A clear showing of the mechanical connection between the release reeds 66 and various standard matrix release mechanisms is shown in Figs. 12 and 13. Upon 75 the return movement of the bail 62 the push 'bar 36 is permitted to gravitate back to its normal position, augmented to someextent by spring 81 which primarily serves to pull it inwardly toward its solid line position and also by springs individually associated with the release reeds 66 of the principal machine. Before this occurs the selected bar 35 is restored to its solid line position by a restoring cam rod 88 and is thus held momentarily until a new positionment of the code bars 34 blocks it by intel-posing projections 69 instead of an alignment of notches 1i in the path of movement of its teeth 12. An overlap is afforded between the operation ofthe push bars 36 and their respective selector bars 35 which corresponds to the overlap provided by the well known cam and rubber roller release means of the commercial linecasting machines. The present construction is a. more accurate and positive performance, however, and is effective as follows. When upon the selective movement of a bar 35 a push bar 38 is displaced and is raised into actuating position asI shown in Fig. 4a it is maintained in this position by the engagement of bar E8 with its forward edge thereby permitting its corresponding selector bar 35 to be reset preparatory to the next selection. The spring 81, :comprising a universal coupling between the selector and push bars, does not interfere with the independent action of either of them.

Each of the several selecto-r bars is confined to a limited, longitudinal and parallel movement by having at its foremost end an elongated slot 13 through which is placed a rod 14, and by having at several points throughout its length transverse supporting combs 15. The forward movement of the bars 35 is definitely limited by the abutment of its shouldered portion 18 and the forward edge of the transverse bar 11.

The code bars 34 are reset to a normal position (Fig. 3) at each rotation of the cam shaft 41. As cam 18,-which is secured to shaft 41, makes a rotation it permits bell crank 19 to respond to the urge of its spring by presenting the nadir or low part of its cam. surface to the roller 98, but with the continued rotation of the shaft 41 a rise in the cam 18 returns the bell crank 19 and its resetting bail 8|, to its extreme left hand position, thereby permitting of a new selection of the code bars 34. Thus, since the shaft 41 makes a complete revolution in response to each signal, the cam 18 operates to .reset the code bars at the same frequency.

With particular reference` to Figs. 7 and 8 attention. is again directed to the lifting bail 82 Whose function, as described above, to lift the push bars 36 as they are selected so that they operate corresponding matrix rele-ase reeds 8E, Fig. 1. At each end of the bail 62 is an ear S2 through which passes a rocker shaft 83 secured to said ears, and intermediate the ends is a pivot lug 84 to which is connected a link 85. A lever 86 is pivotally mounted on the transverse rib 54 of the framework and is pivotally articulated to the other end of the link 85. The free end of the lever 86 carries a cam roller 81 which follows the peripheral surface of cam 88 as` it is rotated by the cam shaft 48 and imparts thereby a reciprois provided a convenient mode of manually controlling the machine in the absence of the removable keyboard, since it would then. be necessary only to displace the desired push bars by hand which may be done by pushing the lug 8| thereof.

The cam rod 68 is pivoted at its extremities which are suitably journalled in the framework. A link 92 is pivotally connected to an ear 83 integral with the cam rod 68 and at its opposite end is pivotally articulated to a first classlever 94 which is freely mounted on shaft 48. The opposite end of the lever 94 carries a cam roller 95 disposed to engage the peripheral edger` of cam 96 of the cam shaft 41. Spring 91 urges the cam roller 95 against cam 96 and in cooperation with it imparts a timed., reciprocal movement to the cam rod 68.

Reference is again made-to Fig. 2. As already indicated, shafts 41 and 48 are extensions of shafts 43 and 42, respectively. Shaft 43 is adapted to be coupled with extension shaft 41 through the medium of a .spring urged tooth clutch 98 the slidablemember 99 of which carries a disengaging cam projection illustrated in Fig. 9. A release electro-magnet |82 isI mounted below the clutch, and an armature |83 pivoted at |84 is adapted to be influenced by electro-magnet |02. A lever pivoted at |86 carries asetting roller |81 and is provided with a suitable cam engaging portion |88 which is adapted to lie in the path of the projection ||l| as it is revolved and to engage a beveled side thereof so that by the camming action of the lever |65 upon the projection IUI the slidable member 99 of the clutch is thereby disengaged from the secured member |89.' The lever |85 is normally held in position to disengage the clutch 88, as indicated in Fig. 9, by the armature |83, but upon the energization of the electro-magnet |82 the armature |83 is moved out of position and the lever |85 is permited to yield to the influence of its spring and be moved out of engagement with the cam projection |8|. After the armature |83 'is ,released by its magnet, the continued rotation of the shaft 41 carries cam ||2 into engagement with the resetting roller |81 of the lever and working against the action. of spring resets the lever to its normal and engagement positions where it is so held by the armature |83.

The shaft 42 maintains a driving engagement with shaft 48 through the medium` of a tooth clutch ||3 which is similar to clutch 98 just described. The release of the movable member of this clutch whereby is effected its engagement with the secured member, is mechanically controlled from the aforementioned sha-ft in the following manner. This clutch is provided with a lever ||4 Fig. 9 carrying a resetting roller ||5 operative in the same manner as the lever |85 and roller |81 of the clutch 98. Instead of an armature, however, there is a simple lever ||6 pivotally linked to a trigger l l1 one end of which is disposed in the path of rotation of apex H8 of a release cam |9 on shaft 41. This cam is so positioned on its shaft that shortly after it is started into rotation. it engages the trigger |1 to correspondingly release shaft 42 for rotation, but since this latter shaft has a somewhat higher speed of rotation the two are brought to stop position at the end of each revolution at nearly the same time. Thus it will be understood that shaft 41 is. controlled by the magnet |82 and that shaft 48 is controlled from shaft 41.

When the unit is to be operated by hand as explained above in connection with the push bar lugs 9|, the shaft 48 is released by a special arrangement. In that case the movement of a push bar 36 rocks a universal bar |66 Fig. '1 which is connected to the lever ||6 by a link III). 'I'hus the shaft 48 is released to rotate and to effect the movement of the bail 62.

From the foregoing description it should now be clear how that part of the mechanism operates that relates to the release of matrices from their storage magazines, but for purposes of organizing the several functions involved the operation will again be summarized in connection with the following description.

Let it be assumed that a set of transverse perforations in the tape 32 has presented itself over the record reader feelers 45. In accordance with each hole or absence thereof the corresponding feeler will assume an elevated position or remain in a depressed position as shown in Fig. 3. Since each feeler 45 has connected to it, by disc and socket connection as at |22, a rod 46, the latter assumes a corresponding position. Each of these rods 46 has integrally therewith a lug |24 adapted, when the rod 46 is up,- to present itself into the path of the oscillating hammer bail |25. As viewed in Fig. 3 the code bars 34 are each urged to the left by'individual coil springs |26. A trigger lever |21 pivoted at |28 is provided for each bar 34 to lock it in its extreme iight position, but when operated by counterclockwise rotation against the action of its spring |29, it permits the movement of its code bar 34 as influenced by the spring |26. A pin |3| is provided for each trigger lever |21 and is adapted to transmit the lateral movement of an associated one of the rods 46 thereto.

In this manner those rods 46 which are in the upward position pursuant to a particular code combination of perforations and present their lugs into the path of the hammer bail |25 will be pivoted, by the impact of said bail, about their connection |22 and will through the pins |3| impart a corresponding movement to the trigger levers |21 thereby releasing the code bars 34 thereof. The remaining rods not being in position to be engaged by the hammer bail |25, their corresponding code bars remain in their right hand position.

On the left end of shaft 41 are two cams |32 and |33. As also indicated in Fig. 3 the cam |32 engages a roller |34 carried by a vertically sliding support |35 supported in the record reader frame and in cooperation with the springs |36 (Fig. 6) imparts a reciprocating movement to said support. The upper end of the support |35 carries a bracket |31 which engages the pro-` jecting portions |38 of the feeler levers 45 and on its downward movement it carries all of the feelers with it. On its upward movement the bracket permits the feelers to rise in response to the urge of their individual springs |39 and to position themselves in accordance with the perforations in the tape 32.

The other cam |33 acts upon a roller |4| of a bell crank |42, Fig. 6, and is opposed by a spring |43 connected to a link |44 which is pivoted to the bell crank |42. The hammer bail |25 is connected to the link I 44 and in this manner receives reciprocal motion.

It will be noted from Fig. 3 that the lower ends of the rods 46 extend below the point at which the lug and pin engagement is located. This is provided for the purpose of additional control. Thus, a set of signal magnets |45 each having an armature |46 are so disposed that the movement of said armatures causes a corresponding movement of the rods 46. In this manner electrical signals transmitted from a suitable source such as the tape transmitter illustrated in Fig. 5b may be made to control the device in a manner generally similar to that described above.

Spring loaded plungers |41 having push'button terminals |48 at the outer ends thereof are supported in a block |49. They are so spaced that the opposite ends |5| thereof` abut the rods 46, each to each, so that by depressing any of these plungers one may impart the same movement to said rods 46 manually that may be produced electrically or mechanically in either of the methods aforementioned. This mode of operation is intended as a convenience for testing, adjusting or correcting errors in connection with the foregoing methods of operation.

No matter which of the several methods of actuating the record reader mechanism may be used, the subsequent operations are the same. In all cases a definite positionment is effected upon the several code bars 34. This results in the alignment of a transverse row of notches 1| Figs. 5 and 9 in the several code bars and the movement to the right of a selector bar 35 into the particular alignment when permitted to do so by the clockwise oscillation of the cam rod 68 as best illustrated inv Fig. 5. This movement is urged by the individual spring 6| and continues until the shoulder 16 abuts the transverse bar 11 whereupon the corresponding push bar 36 is displaced to assume the position indicated in dotted lines. At this time the bail 62 revolves clockwise and its lip 63y hitting the depending leg 64 thrusts the bar 36 upwardly to actuate the matrix release reed 66.

Following this a matrix 80 is released from its magazine in the usuall manner, with which the art is well acquainted, and forthwith discharged into the chute leading to an assembling elevator |56 Fig. 1. Upon this elevator there is carried an assembly block |51 onto which are discharged the matrices and space bands in the process of line composition. This in substance includes the features that relate to composing and line setting control. In addition to this, however, the present invention also includes control for the line casting operations of the principal machine.

Elevato?` mechanism Attention is now directed to Figs. 1, 3, 5, 8, 16 and 17. The drive shaft 42 carries secured to it a worm gear |58 which is adapted to drive a worm wheel |59 fixed to the stub shaft 49 located below and at right angles to the drive shaft. A cam sleeve 52, Fig. 5, of the stub shaft 49 is adapted to be driven by the stub shaft through the medium of a tooth clutch |6| generally similar to the clutches 98 and ||3 aforementioned. As best indicated in Figs. 10 and 11, this clutch |6| differs in one respect, however, from the other clutches. Instead of there being b ut one lever for disengaging the clutch there are two; namely, |62 and |63. Thus, the driven shaft 52 may be arrested in either of two positions spaced 180 apart from each other. As will be explained hereinafter in connection with the elevator safety mechanism, the release of lever |63 is effected upon the return of the delivery slide arm 224 after a delivery operation, while the release of lever |62 is effected at the instance of an elevator signal by the trigger 2|3. At each of these events the release of the respective levers |62 or |63 causes engagement of clutch I 6| for a 180 revolution of the shaft 52.

A cam |64 secured for rotation with said driven shaft 52 engages a roller |65 carried by a bell crank lever |66 pivoted at |61 to the depending portion 51 of the framework. The other arm |68 of the bell crank |66 has pivotally secured to it. one end of a push rod |69 the other end |1| of which is pivotally connected to one arm of another bell crank |12. In order to render said push rod resiliently yieldable it has intermediate its extremities a dash pot |13 and a coil spring |14 disposed to normally maintain said rod in extended position. The other arm of the bell crank |12 is pivotally connected to the lower end of an elevator shaft |15. In this'manner the rotation of the cam |64 is, adapted, through the linkage described, to raise and permit the lowering of the assembly elevator |56 through the shaft |15.

The proper time for raising the elevator |56 is when its assembly block |51 has received a full load of matrices and space bands so as. to be able to cast a full measure line. Any load that is too long must be rejected else it will lock the casting machine While one that it too short should also be rejected otherwise the mold will be unable to retain it. To safe-guard against either of these contingencies there is provided herewith a measuring mechanism and safety means indicated hereinafter as the short-long line interceptor. The preferred form of this device is illustrated in detail in Figs. 14 and 15. The bell crank |12 is provided with a segment |16 having a notch |11 in its periphery into engagement with which/ a pawl |18 pivoted at |19 is urged by a spring 293 when permitted to do so. The opposite end of the pawl 18 is pivotally connected to a depending arm |8| of a bushing |82 supported for pivotal as well as longitudinally slidable movement upon a vertical stud shaft |83. An arm |84 secured to said bushing |82 extends in the direction of the assembling elevator |51 with a slight upward incline andl terminates with a vertical pin |85. Another arm |86 secured to the bushing |82 terminates with a fork |81 adapted to straddle the threads |88 of and be moved by a feed worm |89. The worm |89 is secured to a stub shaft |9| journaled in a yoke |92. A torsional spring |93 secured to one bow of the yoke |92 and to the worm |89 tends to normally maintain the latter member angularly in its extreme counterclockwise or starting position. On the opposite end of the shaft |9| is secured a ratchet wheel |94 which is rotated one tooth distance for each horizontal movement of the space band selector bar |95. Thus every time a signal is received for dropping a space band, a pawl |96 carried by the space band selector bar |95 in moving forward causes the rotation of the ratchet |94 one tooth distance while a holding pawl |90 maintains it against the tendencies of spring |93 until released. Arm |86 and its associated feeler arm |84 to which it is secured are normally maintained in the position indicated in full lines in Fig. 15, that is,`

before any spacebands are released. As the worm |88 is rotated, arm |86 is drawn leftwardly and the assembly, including arm |84, is then pivoted about shaft |83 in a clockwise direction.

The assembling block |51 affords a trackway into which the assembled matrices are received, while a measuring device is. associated with the assembler slide |91 and is adapted to be moved along with the matrices 80 and serves as a visual guide to the operator for ending the line as well as for proper justification thereof.r Secured to said slide is a clamp |98 the lower end of which carries a triangular plate |99 of a particular shape, materially significant, as will be indicated in the description of its performance. The vertudinal path described by the plate |99 during its movement while matrices are being assembled, but normally a trifle below the plane in which the plate moves as illustrated in Fig. 14 so that during composing operation the plate may pass above the pin.

This device intercepts the movement of the .elevator when a line that is either too short to be expanded to measure or too long to be accommodated hasbeenset up on the assembly block. supposing a short line to have been set up and an elevator signal comes through for raising the block |51. In such case the stick |91 will lonly have advanced in the direction of arrow 20| to a point approaching but not reaching the pin |85. The pin will be in one or another of the positions -in its arcuate path depending on the numben of space bands that have been released to comp-rise the particular line. This position varies from the solid line to the dotted line as indicated in the proportion of space bands from zero to the maximum available or usable. If in such a case enough space bands have been released so that their combined expansion is sui'licient to expand the length of the line to fullline dimension then the pin |85 will have attained a position to be engaged by the plate |99 Fig. 15. If, however, an insufficient number of space bands havebeen so released the pin will operate vertically unobstructed by the plate. Thus it will be seen that as the composed line Vle-ngth increases the plate moves farther in the direction of the arrow and fewer space bands will suiice to accommodate the requirement of engaging the pin |85 with the plate |99. versely as the number of space bands in a particular line is increased a fewer number of matrices 80 will be accommodated dueto the greater expansion of the space bands.

While the elevator |56 is down as in Fig. 14, the tooth 202 of the pawl lever |18 rests upon the peripheral surface of the bell crank segment |16 but as soon as the latterbegins to revolve, the tooth will slip into the notch |11 as urged by spring 203, and the rear end.of the pawl |18 which is connected to the bushing |82wi1l force the latter member upwardly provided, however, that plate |99 does not overlap the pin |85. If thepin |85 is overlapped by the plate the interference by the latter will prevent the bushing |82 from sliding upwardly and the pawl lever from entering into the segment notch |11. In opposite manner a short line with insufficient space bands, permitting of no engagement of the Contical pin |85 of arm |84 is disposed in the longipin |85 by the plate |99 permits the pawl |18A to drop into the notch |11 to arrest the movement of bell crank |12. During such a condition the continued movement of the elevator cam |64 imparting a rotation to bell crank |66 causes a compression of spring |14 while piston 204 (Fig. 16) moves into the far end of its dash pot |13.

Suppose, however, instead of the line being too short, that it is too long. In that event, the plate |99 will over-ride the range of the pin |85 and will assume a position; for example, such as indicated in dotted lines in Fig. 15. In this case the expansion of the space bands constitutes no consideration since the line is already too long,

hence the rear edge 205 of the plate |99 is approximately a straight line instead of being inclined as in the case of the forward edge 206. The pin |85 will then be permitted to rise behind the plate |99 affording thereby a, similar interception of the bell crank and elevator |56. Thus,

the length of line assembled.

During the time that the elevator |56 and its assemblingblock |51 are in transit further release of matrices and space bands must be arrested otherwise they are discharged out of .the chute onto the oor since the assembler block is not there to receive them. This interruption is automatically controlled in the present device by mechanism whereby when operation of the elevator is begun, the control tape 32, or

.rather the feed mechanism 33 therefor, is

stopped. Particular reference is had to Figs. 2, 8, 16 and 17 When a signal comes through for operating the elevator mechanism, a particular selector bar 201 (Figs. 16 and 17) is selected and moves rearwardly as already explained in connection with matrix selector bars. This bar 201 differs structurally from the matrix selector bars 35 by terminating with a lug 2|0 as does the bar indicated in Fig. 9, and by having no push rod 36 in conjunction. As can be seen, the movement of the bail 62 will then raise the bar 201 bodily. This movement is permitted by the special olf-set construction 200 which amply clears the transverse bar 11. In addition this elevator selector bar 201 is also supplied with two appendages one of which engages a lug 209 of a bent member 2| I which in turn is secured to a shiftable rack 2|2, and the other of which engages a clutch release trigger 2|3 (Fig. 8). In its forward movement `bar 201 moves rack 2 I2 laterally while in its upward movement, upon the operation of bail 62 it effects the release of the trigger 2|3 which is pivotally connected to the clutch release lever |62 aforementioned and also illustrated in Fig. 10.

Rack 2I2 pivotally supports a third class lever 2|4 the free end 2I5 of which is adapted to close a set of spring contacts 2|6 through the medium of a longitudinally slidable switch arm 2|1. The force for actuating said lever is communicated to it by a bell crank 2|8, spring urged away from it by a spring 230, Fig. 17, but actuated to engage it when a revolving pin 2 I 9 cams against the lower arm 22| of the bell crank 2|8, Fig. 17. The lever 2|4 is provided with a notch 222 and is so designed that when the rack 2|2 is in its normal position andthe bell crank 2|8 is actuated by pin 2I9, the upper arm 223 does not pass into the notch 222 but engages the shoulder 220 of the lever 2I4 causing it to be moved and through switch arm 2 I1 close the contact springs 2|6. When the rack 2 I2 moves into its actuated position then the arm 223 of the bell crank 2 I8 registers with the notch 222 and thus arm 223 does not impart movement to the lever 2I4. During the normal stop position of the shaft 52, the pin 2 I 9 is in the upward position, approximately as shown in Fig. 17 so that the contacts 2|6 are normally closed as shown in Fig. 5a., but during the other stop position the pin 2 I 9 is out of the way thereby permitting spring 230 to withdraw end 223 of bell crank 2 I0 from notch 220 and permitting the contacts 2 I6 to remain opened. Immediately following an elevator signal the elevator selector chine that the elevator |56 has been relieved of the matrices by the delivery slide, and that the machine is ready to proceed with another line composition. This signal is received from the delivery slide arm 224 in the following manner.

The assembling elevator proceeds upwardly with its load of matrices 80 for casting a slug. When it reaches the top of its travel it releases the delivery slide arm 224 which is pivoted just below the frame', of the elevator. 'Ihis arm 224 while in its normal position maintains two L shaped control levers 225 and 226 in the position indicated in Fig. 8 but when released permits them to be pivoted into the position indicated in dotted lines in Fig. 14.

One of the arms 225 is secured to a bail 221 pivoted on a shaft 228. A link 229 is connected to the bail at 23|, to a propelling spring without numeral, Fig. 16, and to one end of a rst class lever 232 Fig. 16 which is suitably mounted on a stud shaft 233 secured in a wall 51, while the other end of the lever 232 is pivotally connected to a beam 234 the opposite end of which is bifurcated (Fig. 10). A fixed rod 235 passes between the forks 236 and thereby supports the free end of the beam 234 which has intermediate its extremities a pawl 231 spring urged in a counterclockwise direction to engage a depending leg 238 of the clutch lever |63. In moving to the right as viewed in Fig. 10 the pawl yields and passes under the leg 238 but in moving to the left it is adapted to engage the leg and thereby release the clutch I6I when shaft 52 has been arrested in its operative stop position (as distinguished from its normal stop position). In this manner the return movement of the slide arm 224 releases the clutch permitting another 180 revolution of the shaft 52 and the return of the assembling elevator |56 after having completed the delivery of a load of matrices to the mold.

When the assembling elevatoris returning toward the conclusion of the performance, the bell crank lever |12 is restored to the normal position indicated in solid lines in Figs. 3 and 16. When this occurs a pin 239 projecting from the side of segment |16 of the bell crank |12 engages a depending portion 24| of a long slide bar 242 the .other end 243 of which supports the bell crank 2|8 (Fig. 17) and pulls it longitudinally so as to dispose the bell crank 2|8 into the range of the switch lever 2|4. In this connection it Will be noted that another member 244 projecting from the segment |16 is adapted to engage the depending portion 24| of the slide bar 242 when the elevator is up and the bell crank is in its dotted position. This latter performance pushes the slide bar 242 and the bell crank |12 connected to it` out of range of engagement with the switch arm 2 I1. The reason for this control of the switch 2 I1 from the elevator mechanism is so that the restoring of the cam shaft 52 to normal by the movement of the delivery slide arm 224 and the consequent disposal of the cam` pin 2I9 into contact closing position does not close the operating circuit but that engagement of pin |39 with depending portion 24| operates slide box 242 to ating parts of the principal'machine are in normal position and that the machine is ready to continue with the line composition.

The other of the two L shaped arms 226 is secured to a bushing loosely mounted on the shaft 228 Fig. 8. A leg 245 extends from this bushing and is normally disposed to clear a lug 246 integral with the lo-ng arm 241 of the bell crank |12 (Fig. 14), when the latter member is rotated during operation of the elevator. On the contingency, however, of the delivery slide arm 224 being withheld from returning, as by a jamming of the matrices 80 subsequently to their discharge and before delivery to the mold or for any other reason, this leg 245 urged by spring 248 will then continue to assume the position indicated in dotted lines, another operation of the elevator thereby being prevented and also the delivery of another load of matrices and the possible further complication that would otherwise ensue.

Quadding-out mechanism 4single signal.

This feature of the invention forms the subject matter of a divisional application Serial No. 720,409, led April 13, 1934.

lThe em quad push bar 36 is provided with an extension 360 over which normally rests one arm of a'T lever 36| and which lever is thereby restrained from responding to the clockwise torque imparted to it by spring 362. Over another arm of the'lever 36| there is vertically disposed a wedge bar 363 capable of limited longitudinally slidable movement. 'Ihe upper end of bar 363 is provided with a cam surface adapted-toy cooperate with a corresponding surface of a horizontally slidable bar 364 which carries an adjustable abutment clamp 365. A depending arm 366 is secured to the slide |91 and is adapted to engage clamp 365 at a predetermined time with respect to a line composition and to move bar 364 and thereby cam vertical bar 363 downwardly to rotate lever 36| counterclockwise and against the. action of its spring 362.

In operation, when the em quad push bar 36 is selected and moved into the position indicated in dotted lines in Fig. 14h the extension 360 is thereby removed from interference with lever36| and the latter member is permitted to rotate clockwise (Fig. 14a) to assume its dotted line position and to raise the vertical bar 363 at the same time camming horizontal bar 364 to the right. In this position the adjacent arm of lever 36| blocks extension 366 of the em quad push bar 36 preventing the return of the latter and causing it to Ibe maintained in its dotted line position and to be actuated` continuously by the bail 62. During this condition the T-lever 36| permits the contacts 361 to come ajar .thereby breaking the control circuit of Fig. 5a. and arresting the record reader. k

When a suiicient number of em quad matrices have been assembled the arm 366 being secured to the slide |91 engages the abutment clamp 365 moving bar 364 to the left and bar 363 downwardly rotating lever 36| counterclockwise and closing the contacts 361. This permits extension 360 to move back into its solid line position and l retain the T-lever 36| `in its normal position.

Fordiiferent line lengths it is only necessary to adjust clamp 365 in accordance with corresponding markings on the bar 364.

M ulti-channel shift As is well known in the art, each type of letter or character matrix 8U is provided with a separate channel in the storage magazine, Among the several matrices are a iew (the em quad for example) that are more frequently used than the rest, so much so that o-fttimes the capacity of a single matrix channel is not sulicient to accommodate thenumber of occurrences that such a character may have in the course of a single cycle of operation. To remedy such a situation two channels are provided to contain each class of such frequently used matrices 80 and an alternative shift bar 249 which operates as an extra code bar as indicated in Fig. 5. This particular bar is so designed that it will interfere with none but the selection of the frequently used matrices and this is accomplished by providing it with notches n all but the positions in which the particular selector bars are concerned. There being two channels tol be thus alternatively controlled there are accordingly two selecto-r bars, one for each channel which in turn are controlled by a bar 249 operating to block one or the other of these selector bars in accordance with whether it is moved to one side or the other. The movement of the bar 249 is-rnade regularly and alternatelyby operation of the elevator cam shaft 52 upon which is secured a gear 25| which engages and drives a larger gear- 252, twice the size of the smaller 25| so that the latter makes two revolutions to each one of that made by the channels containing the frequently used matrices 80, and the succeeding half-revolution will prepare thevother, since the code bar 249 as indicated above is equipped with a pair oi projections 250 for each set of channels to be controlled, and

since these projections are so spaced that during each of the two positions that the bar 245 assumes one of these projections 253 blocks one of the pair of selector bars while the other is not blocked but permitted to move into operative position.

The foregoing feature is claimed in copending divisional application Serial No. '124.025, lled May 5, 1934.

Matrix-rail shift Onmost line casting machine matrices there are provided two types of letters. or characters and usually where one type is a roman letter the other is bold face, italics or small caps. The purfro 

